Arterial blood gases during raised intracranial pressure in anesthetized cats under controlled ventilation

Physiologic parameters of the Cushing reflex

The effects of increased intracranial pressure and blood gas tensions on systemic blood pressure were examined in this study. Intracranial pressure was raised hydrostatically and blood gas tensions, blood pressure, and respiration were monitored in anesthetized dogs. Small gradual increments in intracranial pressure resulted in increased cerebral venous carbon dioxide tension, followed by increased respiration, a gradual rise in blood pressure, and finally an increase in heart rate. The results of this study indicate that blood pressure changes appear to be determined by alterations in carbon dioxide tension following increases in intracranial pressure; small increases in intracranial pressure elicit a cluster of physiologic responses, all directed toward stabilization of local cerebral carbon dioxide tension.

Vasopressor responses and hypoxemia with acutely increased intracranial pressure

We studied anesthetized dogs subjected to graded increases in intracranial pressure (ICP) to assess the role of the systemic vasopressor (Cushing) response in the arterial hypoxemia associated with increased ICP. The arterial PO2 decrement was significantly greater with rapidly increased ICP compared to slowly increased ICP (P less than 0.01). Systemic vasopressor responses generated in cats by direct electrical stimulation of the vasomotor center resulted in arterial hypoxemia during controlled ventilation. Therefore, arterial hypoxemia was coincident with increased systemic blood pressure produced by either elevation of ICP or electrical stimulation of the vasomotor center.

Amelioration of hypoxemia by neuromuscular blockade following brain injury

Brain injury has been commonly associated with respiratory failure and uncontrolled skeletal muscle activity. In the present study, neuromuscular (NM) blockade induced by injection of succinylcholine hydrochloride was used to block uncontrolled muscle contractions in dogs with brain injury caused by rapid elevation of intracranial pressure (ICP). Decerebrate posturing, a decrease in value (mean +/- SEM) of arterial oxygen tension (Pa02) of 26 +/- 1 torr, and an increase in arterial carbon dioxide tension (PaCO2) of 11 +/- 1 torr occurred in the dogs, which were supported by mechanical ventilation. The arterial hypoxemia developed independently of the decerebration; however, dogs that demonstrated decerebrate posturing exhibited significantly larger decreases in Pa02 than dogs that did not (P less than 0.01). NM blockade ameliorated the effects of elevated ICP on the arterial blood gases; i.e., the amount of hypoxemia in decerebrate dogs was significantly less in dogs subjected to NM blockade than in dogs not subjected to NM blockade. It is concluded that uncontrolled skeletal muscle activity that exacerbates arterial hypoxemia associated with brain injury is ameliorated by use of NM blockade as a therapeutic adjunct to mechanical ventilation.

Experimental neurogenic pulmonary edema Part 2: The role of cardiopulmonary pressure change

Pressure changes in the aorta, left atrium, and main pulmonary artery were measured before, during, and after inducing increased intracranial pressure in cats. By selectively controlling each of the three pressures, it was concluded that pulmonary arterial hypertension is the single most important precursor of experimental neurogenic pulmonary edema. An earlier observation that neurogenic pulmonary edema may develop in the absence of systemic arterial hypertension was confirmed.

Experimental neurogenic pulmonary edema. Part 1: The role of systemic hypertension

Neurogenic pulmonary edema (NPE) was produced consistently in normal cats by increasing intracranial pressure with an intraventricular infusion of mock cerebrospinal fluid. The usual elevation of systemic arterial pressure (SAP) that follows severe intracranial hypertension (the "Cushing response") was controlled by blood withdrawal at variable rates to achieve and maintain constant cerebral perfusion pressure (CPP) in three groups of cats of 50, 20, and 0 mm Hg, respectively, for 30 minutes. In this model, NPE occurs in the absence of increased SAP and in the presence of decreasing CPP. These results indicate that systemic arterial hypertension is not an essential stimulus for the development of NPE, and suggest that the lungs are directly affected by the intense sympathetic discharge evoked by severe intracranial hypertension.